Your search keyword '"Brodsky, Stanley J."' showing total 616 results

1. Determination of the QCD running coupling in the entire perturbative regime from a single experiment using the Principle of Maximum Conformality

Author

Di Giustino, Leonardo, Brodsky, Stanley J., Ratcliffe, Philip G., Wang, Sheng-Quan, Wu, Xing-Gang, Di Giustino, Leonardo, Brodsky, Stanley J., Ratcliffe, Philip G., Wang, Sheng-Quan, and Wu, Xing-Gang

Abstract

We present a new approach for determining the strong coupling $\alpha_s(Q)$ over the entire perturbative range of validity, for scales from $\Lambda_{\mathrm{QCD}}$ up to the Planck scale ${\sim}10^{19}$\,GeV, with the highest precision and using the data of just a single experiment. The results obtained with this method are consistent with world averages and exhibit improved precision with respect to previous reports. \pacs{12.38.Bx, 13.66.Bc, 13.66.Jn, 13.87.-a,11.10.Gh, Comment: 7 pages, 4 figures

Published

2024

2. The strong coupling in the nonperturbative and near-perturbative regimes

Author

de Teramond, Guy F., Paul, Arpon, Brodsky, Stanley J., Deur, Alexandre, Dosch, Hans Gunter, Liu, Tianbo, Sufian, Raza Sabbir, de Teramond, Guy F., Paul, Arpon, Brodsky, Stanley J., Deur, Alexandre, Dosch, Hans Gunter, Liu, Tianbo, and Sufian, Raza Sabbir

Abstract

We use analytic continuation to extend the gauge/gravity duality nonperturbative description of the strong force coupling into the transition, near-perturbative, regime where perturbative effects become important. By excluding the unphysical region in coupling space from the flow of singularities in the complex plane, we derive a specific relation between the scales relevant at large and short distances; this relation is uniquely fixed by requiring maximal analyticity. The unified effective coupling model gives an accurate description of the data in the nonperturbative and the near-perturbative regions., Comment: 15 pages, 4 figures

Published

2024

3. Comment on P.M. Stevenson, ''Maximal conformality' does not work', Phys. Lett. B 847 (2023) 138288

Author

Brodsky, Stanley J., Di Giustino, Leonardo, Ratcliffe, Philip G., Wang, Sheng-Quan, Wu, Xing-Gang, Brodsky, Stanley J., Di Giustino, Leonardo, Ratcliffe, Philip G., Wang, Sheng-Quan, and Wu, Xing-Gang

Abstract

In his recently published article [1], P.M. Stevenson has claimed that the "principle of maximum conformality (PMC) is ineffective and does nothing to resolve the renormalization-scheme-dependence problem", concluding that the successes of PMC predictions is due to the fact that the PMC is a "laborious, ad hoc, back-door" version of the principle of minimum sensitivity (PMS). We point out that these conclusions are incorrect, being drawn from a misunderstanding of the PMC and the overestimation of the PMS. The purpose of the PMC is to achieve precise fixed-order pQCD predictions, free from conventional renormalization-scheme and -scale ambiguities. We have demonstrated that the PMC predictions satisfy all the self-consistency conditions of the renormalization group and standard renormalization-group invariance; the PMC prediction is thus independent of any initial choice of renormalization scheme and scale. Such scheme independence is also ensured by the commensurate scale relations among different observables. In the $N_C\to 0$ Abelian limit the PMC method reduces to the well-known Gell-Mann--Low method for precision calculations in Abelian QED. Owing to the elimination of the factorially divergent renormalon terms, the PMC series generally has better convergence behavior than the conventional series, can substantially suppress any residual scale dependence due to unknown higher-order terms, and thus provides a reliable basis for estimating the contributions of the unknown higher-order terms. The full Abstract and detailed explanations are given in the body of the text., Comment: 5 pages, no figures

Published

2023

4. High precision tests of QCD without scale or scheme ambiguities

Author

Di Giustino, Leonardo, Brodsky, Stanley J., Ratcliffe, Philip G., Wu, Xing-Gang, Wang, Sheng-Quan, Di Giustino, Leonardo, Brodsky, Stanley J., Ratcliffe, Philip G., Wu, Xing-Gang, and Wang, Sheng-Quan

Abstract

A key issue in making precise predictions in QCD is the uncertainty in setting the renormalization scale $\mu_R$ and thus determining the correct values of the QCD running coupling $\alpha_s(\mu_R^2)$ at each order in the perturbative expansion of a QCD observable. It has often been conventional to simply set the renormalization scale to the typical scale of the process $Q$ and vary it in the range $\mu_R \in [Q/2,2Q]$ in order to estimate the theoretical error. This is the practice of Conventional Scale Setting (CSS). The resulting CSS prediction will however depend on the theorist's choice of renormalization scheme and the resulting pQCD series will diverge factorially. It will also disagree with renormalization scale setting used in QED and electroweak theory thus precluding grand unification. A solution to the renormalization scale-setting problem is offered by the Principle of Maximum Conformality (PMC), which provides a systematic way to eliminate the renormalization scale-and-scheme dependence in perturbative calculations. The PMC method has rigorous theoretical foundations, it satisfies Renormalization Group Invariance (RGI) and preserves all self-consistency conditions derived from the renormalization group. The PMC cancels the renormalon growth, reduces to the Gell-Mann--Low scheme in the $N_C\to 0$ Abelian limit and leads to scale- and scheme-invariant results. The PMC has now been successfully applied to many high-energy processes. In this article we summarize recent developments and results in solving the renormalization scale and scheme ambiguities in perturbative QCD. [full abstract is in the paper]., Comment: 83 pages ; 22 figures; Review article published on Prog. Part. Nucl. Phys. arXiv admin note: substantial text overlap with arXiv:2205.03689

Published

2023

5. Entropy from entangled parton states and high-energy scattering behavior

Author

Dosch, Hans Gunter, de Teramond, Guy F., Brodsky, Stanley J., Dosch, Hans Gunter, de Teramond, Guy F., and Brodsky, Stanley J.

Abstract

The relation between the gluon density in a hadron and entanglement entropy can shed a new light on the high energy scattering behavior of hadrons. Using the holographic light-front QCD framework the growth above the classical geometric cross section is directly related to the increase of the internal quantum entropy from the entangled parton distribution in hadrons. A rather consistent picture emerges from the scale dependence of the Pomeron from the QCD evolution of the gluon distribution function $g(x, \mu)$, the rising of the integrated cross section in photoproduction of vector mesons, the deep inelastic scattering (DIS) experiments at HERA, hadron multiplicity and quantum entropy. We also point out a possible analogy between parton entanglement entropy and the black-hole entropy of Bekenstein and Hawking., Comment: 17 pages, 4 figures, updated references

Published

2023

6. 50 Years of quantum chromodynamics

Author

Gross, Franz, Klempt, Eberhard, Brodsky, Stanley J., Buras, Andrzej J., Burkert, Volker D., Heinrich, Gudrun, Jakobs, Karl, Meyer, Curtis A., Orginos, Kostas, Peláez Sagredo, José Ramón, otros, ..., Gross, Franz, Klempt, Eberhard, Brodsky, Stanley J., Buras, Andrzej J., Burkert, Volker D., Heinrich, Gudrun, Jakobs, Karl, Meyer, Curtis A., Orginos, Kostas, Peláez Sagredo, José Ramón, and otros, ...

Abstract

Review firmado por 84 autores Texto Funding from Spain: MINECO through the “Ramón y Cajal”program RYC-2017-21870, the “Unit of Excellence María de Maeztu 2020–2023”award to the Institute of Cosmos Sciences (CEX2019-000918-M) and from the grants PID2019-105614GB-C21 and 2017-SGR-929 (J.Virto); The Spanish Ministerio de Ciencia e Innovación grant PID2019-106080GB-C21 and the European Union’s Horizon2020 research and innovation program under grant agreement No 824093(STRONG2020) (J.R.Peláez); European Research Council project ERC-2018-ADG-835105YoctoLHC, by Maria de Maetzu excellence program under Project CEX2020-001035-M, by Spanish Research State Agency under project PID2020-119632GB-I00,and by Xunta de Galicia (Centro singular de investigación de Galicia accreditation 2019–2022), by European Union ERDF(M.Escobedo); The Spanish Ministerio de Ciencia e Innovación grant PID2021-122134NB-C21 and by the Generalitat Valenciana under grant CIPROM/2021/073 and by CSIC under grant LINKB20065 (M.Vos)., 2023 Descuento SCOAP, Quantum Chromodynamics, the theory of quarks and gluons, whose interactions can be described by a local SU(3) gauge symmetry with charges called "color quantum numbers", is reviewed; the goal of this review is to provide advanced Ph.D. students a comprehensive handbook, helpful for their research. When QCD was "discovered" 50 years ago, the idea that quarks could exist, but not be observed, left most physicists unconvinced. Then, with the discovery of charmonium in 1974 and the explanation of its excited states using the Cornell potential, consisting of the sum of a Coulomb-like attraction and a long range linear confining potential, the theory was suddenly widely accepted. This paradigm shift is now referred to as the November revolution. It had been anticipated by the observation of scaling in deep inelastic scattering, and was followed by the discovery of gluons in three-jet events. The parameters of QCD include the running coupling constant, as (Q(2)), that varies with the energy scale Q(2) characterising the interaction, and six quark masses. QCD cannot be solved analytically, at least not yet, and the large value of alpha(s) at low momentum transfers limits perturbative calculations to the high-energy region where Q(2) >>Lambda(QCD) (2) similar or equal to (250 MeV)(2). Lattice QCD (LQCD), numerical calculations on a discretized space-time lattice, is discussed in detail, the dynamics of the QCD vacuum is visualized, and the expected spectra of mesons and baryons are displayed. Progress in lattice calculations of the structure of nucleons and of quantities related to the phase diagram of dense and hot (or cold) hadronic matter are reviewed. Methods and examples of how to calculate hadronic corrections to weak matrix elements on a lattice are outlined. The wide variety of analytical approximations currently in use, and the accuracy of these approximations, are reviewed. Thesemethods range from the Bethe-Salpeter, Dyson-Schwinger coupled relativistic equations, Programa Ramón y Cajal, Ministerio de Ciencia e Innovación (España), Unión Europea. H2020, Xunta de Galicia, Generalitat Valenciana, Depto. de Física Teórica, Fac. de Ciencias Físicas, Instituto de Física de Partículas y del Cosmos (IPARCOS), TRUE, pub, Descuento UCM

Published

2023

7. Elimination of QCD Renormalization Scale and Scheme Ambiguities

Author

Wang, Sheng-Quan, Brodsky, Stanley J., Wu, Xing-Gang, Shen, Jian-Ming, Di Giustino, Leonardo, Wang, Sheng-Quan, Brodsky, Stanley J., Wu, Xing-Gang, Shen, Jian-Ming, and Di Giustino, Leonardo

Abstract

The setting of the renormalization scale ($\mu_r$) in the perturbative QCD (pQCD) is one of the crucial problems for achieving precise fixed-order pQCD predictions. The conventional prescription is to take its value as the typical momentum transfer $Q$ in a given process, and theoretical uncertainties are then evaluated by varying it over an arbitrary range. The conventional scale-setting procedure introduces arbitrary scheme-and-scale ambiguities in fixed-order pQCD predictions. The principle of maximum conformality (PMC) provides a systematic way to eliminate the renormalization scheme-and-scale ambiguities. The PMC method has rigorous theoretical foundations; it satisfies the renormalization group invariance (RGI) and all of the self-consistency conditions derived from the renormalization group. The PMC has now been successfully applied to many physical processes. In this paper, we summarize recent PMC applications, including event shape observables and heavy quark pair production near the threshold region in $e^+e^-$ annihilation and top-quark decay at hadronic colliders. In addition, estimating the contributions related to the uncalculated higher-order terms is also summarized. These results show that the major theoretical uncertainties caused by different choices of $\mu_r$ are eliminated, and the improved pQCD predictions are thus obtained, demonstrating the generality and applicability of the PMC., Comment: 14 pages, 9 figures, an invited review for the special issue "The Quantum Chromodynamics: 50th Anniversary of the Discovery" for Universe, published version

Published

2023

8. Color symmetry and confinement as an underlying superconformal structure in holographic QCD

Author

de Teramond, Guy F., Brodsky, Stanley J., de Teramond, Guy F., and Brodsky, Stanley J.

Abstract

Dedicated to the memory of our colleague, Harald Fritzsch, who, together with Murray Gell-Mann, introduced the color quantum number as the exact symmetry responsible for the strong interaction, thus establishing quantum chromodynamics (QCD) as a fundamental non-Abelian gauge theory. A basic understanding of hadron properties, however, such as confinement and the emergence of a mass scale, from first principles QCD has remained elusive: Hadronic characteristics are not explicit properties of the QCD Lagrangian and perturbative QCD, so successful in the large transverse momentum domain, is not applicable at large distances. In this article, we shall examine how this daunting obstacle is overcome in holographic QCD with the introduction of a superconformal symmetry in anti de Sitter (AdS) space which is responsible for confinement and the introduction of a mass scale within the superconformal group. When mapped to light-front coordinates in physical spacetime, this approach incorporates supersymmetric relations between the Regge trajectories of meson, baryon and tetraquark states which can be visualized in terms of specific $SU(3)_C$ color representations of quarks. We will also briefly discuss here the implications of holographic models for QCD color transparency in view of the present experimental interest. Invited contribution to the book dedicated to the memory of Harald Fritzsch., Comment: 20 pages, 5 figures, Invited contribution to the book dedicated to the memory of Harald Fritzsch. arXiv admin note: substantial text overlap with arXiv:2212.14028

Published

2023

9. High precision tests of QCD without scale or scheme ambiguities

Author

Di Giustino, Leonardo, Brodsky, Stanley J., Ratcliffe, Philip G., Wu, Xing-Gang, Wang, Sheng-Quan, Di Giustino, Leonardo, Brodsky, Stanley J., Ratcliffe, Philip G., Wu, Xing-Gang, and Wang, Sheng-Quan

Abstract

A key issue in making precise predictions in QCD is the uncertainty in setting the renormalization scale $\mu_R$ and thus determining the correct values of the QCD running coupling $\alpha_s(\mu_R^2)$ at each order in the perturbative expansion of a QCD observable. It has often been conventional to simply set the renormalization scale to the typical scale of the process $Q$ and vary it in the range $\mu_R \in [Q/2,2Q]$ in order to estimate the theoretical error. This is the practice of Conventional Scale Setting (CSS). The resulting CSS prediction will however depend on the theorist's choice of renormalization scheme and the resulting pQCD series will diverge factorially. It will also disagree with renormalization scale setting used in QED and electroweak theory thus precluding grand unification. A solution to the renormalization scale-setting problem is offered by the Principle of Maximum Conformality (PMC), which provides a systematic way to eliminate the renormalization scale-and-scheme dependence in perturbative calculations. The PMC method has rigorous theoretical foundations, it satisfies Renormalization Group Invariance (RGI) and preserves all self-consistency conditions derived from the renormalization group. The PMC cancels the renormalon growth, reduces to the Gell-Mann--Low scheme in the $N_C\to 0$ Abelian limit and leads to scale- and scheme-invariant results. The PMC has now been successfully applied to many high-energy processes. In this article we summarize recent developments and results in solving the renormalization scale and scheme ambiguities in perturbative QCD. [full abstract is in the paper]., Comment: 79 pages ; 21 figures; Review article submitted to Prog. Part. Nucl. Phys

Published

2023

10. Entropy from entangled parton states and high-energy scattering behavior

Author

Dosch, Hans Gunter, de Teramond, Guy F., Brodsky, Stanley J., Dosch, Hans Gunter, de Teramond, Guy F., and Brodsky, Stanley J.

Abstract

The relation between the gluon density in a hadron and entanglement entropy can shed a new light on the high energy scattering behavior of hadrons: The growth above the classical geometric cross section is directly related to the increase of the internal quantum entropy from the entangled parton distribution in hadrons. A rather consistent picture emerges from the scale dependence of the Pomeron from the QCD evolution of the gluon distribution function $g(x, \mu)$, the rising of the integrated cross section in photoproduction of vector mesons, the deep inelastic scattering (DIS) experiments at HERA, hadron multiplicity and entropy. We also point out a possible analogy between parton entanglement entropy and the black-hole entropy of Bekenstein and Hawking., Comment: 17 pages, 4 figures, possible analogy between parton entanglement and the black-hole entropy added, new references included

Published

2023

11. Local two-photon couplings and the J=0 fixed pole in real and virtual Compton scattering

Author

Llanes Estrada, Felipe José, Brodsky, Stanley J, Szczepaniak, Adam P, Llanes Estrada, Felipe José, Brodsky, Stanley J, and Szczepaniak, Adam P

Abstract

© 2009 The American Physical Society., The local coupling of two photons to the fundamental quark currents of a hadron gives an energy-independent contribution to the Compton amplitude proportional to the charge squared of the struck quark, a contribution which has no analog in hadron scattering reactions. We show that this local contribution has a real phase and is universal, giving the same contribution for real or virtual Compton scattering for any photon virtuality and skewness at fixed momentum transfer squared t. The t dependence of this J=0 fixed Regge pole is parameterized by a yet unmeasured even charge conjugation form factor of the target nucleon. The t=0 limit gives an important constraint on the dependence of the nucleon mass on the quark mass through the Weisberger relation. We discuss how this 1/x form factor can be extracted from high-energy deeply virtual Compton scattering and examine predictions given by models of the H generalized parton distribution., Depto. de Física Teórica, Fac. de Ciencias Físicas, TRUE, pub

Published

2023

12. Towards a single scale-dependent Pomeron in holographic light-front QCD

Author

Dosch, Hans Günter, de Téramond, Guy F., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., Deur, Alexandre, Dosch, Hans Günter, de Téramond, Guy F., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., and Deur, Alexandre

Abstract

The Pomeron Regge trajectory underlies the dynamics dependence of hadronic total cross sections and diffractive reactions at high energies. The physics of the Pomeron is closely related to the gluon distribution function and the gluon gravitational form factor of the target hadron. In this article we examine the scale dependence of the nonperturbative gluon distribution in the nucleon and the pion which was derived in a previous article [Phys. Rev. D 104, 114005 (2021)] in the framework of holographic light-front QCD and the Veneziano model. We argue that the QCD evolution of the gluon distribution function $g(x,\mu)$ to large $\mu^2$ leads to a single scale-dependent Pomeron. The resulting Pomeron trajectory $\alpha_P(t, \mu)$ not only depends on the momentum transfer squared $t$, but also on the physical scale $\mu$ of the amplitude, such as the virtuality $Q^2$ of the interacting photon in inclusive diffractive electroproduction. This can explain not only the $Q^2$ evolution of the proton structure function $F_2(x,Q^2)$ at small $x$, but also the observed energy and $Q^2$ dependence of high energy diffractive processes involving virtual photons up to LHC energies., Comment: 22 pages, 6 figures

Published

2022

13. Quantum Chromodynamics Resolution of the ATOMKI Anomaly in ${\rm {^4He}}$ Nuclear Transitions

Author

Kubarovsky, Valery, West, Jennifer Rittenhouse, Brodsky, Stanley J., Kubarovsky, Valery, West, Jennifer Rittenhouse, and Brodsky, Stanley J.

Abstract

Recent observations of the angular correlation spectra in the decays $ {\rm ^4He}^*\to {\rm ^4He}+ e^+e^-$ and $ {\rm ^8Be}^*\to {\rm ^8Be}+ e^+e^-$ have been suggested as due to the creation and subsequent decay to an electron-positron pair of a new light particle with a mass of $\sim 17$ MeV. In this work, we present a calculation of the invariant $m_{e^+e^-}$ mass spectrum of the electromagnetic transition of an excited state of helium and estimate the differential and total width of the decay. We investigate the possibility that the source of the signal is an $e^+ e^-$ pair created by a new electromagnetic decay of $\rm ^4He$ caused by a proposed 12-quark hidden-color Fock state in the ${\rm {^4He}}$ nuclear wavefunction, the "hexadiquark.'' We find that we can fit the shape of the signal with the QCD Fock state at excitation energy ${\rm E^*}\simeq 17.9 $ MeV and a Gaussian form factor for the electromagnetic decay. We address the physical issues with the fit parameters using properties of the hexadiquark state. In light of this work, we emphasize the need for independent experimental confirmation or refutation of the ATOMKI results as well as further experiments to detect the proposed new excitation of ${\rm ^4He}$., Comment: Condensed version, 8 pages, 3 figures, comments welcome

Published

2022

14. Proceedings of the Low-$x$ 2021 International Workshop

Author

Alcerro, L., Krintiras, G. K., Royon, C., Albrow, Michael G., Boettcher, Thomas, Brodsky, Stanley J., Celiberto, Francesco Giovanni, Cerci, Deniz Sunar, Cerci, Salim, Chachamis, G., Colferai, Dimitri, Duan, Weisong, Fabbri, Laura, Giuli, Francesco, Gras, Cristina Sánchez, Klein, Spencer R., Lewicki, Maciej P., Mäkelä, Toni, Jalilian-Marian, Jamal, Melnikov, Dmitry, Nemes, Frigyes, Lopes, Beatriz Ribeiro, Österberg, Kenneth, Petrov, Vladimir, Ragoni, Simone, Santimaria, M., Zhang, Zhiqing, Alcerro, L., Krintiras, G. K., Royon, C., Albrow, Michael G., Boettcher, Thomas, Brodsky, Stanley J., Celiberto, Francesco Giovanni, Cerci, Deniz Sunar, Cerci, Salim, Chachamis, G., Colferai, Dimitri, Duan, Weisong, Fabbri, Laura, Giuli, Francesco, Gras, Cristina Sánchez, Klein, Spencer R., Lewicki, Maciej P., Mäkelä, Toni, Jalilian-Marian, Jamal, Melnikov, Dmitry, Nemes, Frigyes, Lopes, Beatriz Ribeiro, Österberg, Kenneth, Petrov, Vladimir, Ragoni, Simone, Santimaria, M., and Zhang, Zhiqing

Abstract

The purpose of the Low-$x$ Workshop series is to stimulate discussions between experimentalists and theorists in diffractive hadronic physics, QCD dynamics at low $x$, parton saturation, and exciting problems in QCD at HERA, Tevatron, LHC, RHIC, and the future EIC. The central topics of the workshop, summarized in the current Proceedings, were: Diffraction in ep and e-ion collisions (including EIC physics); Diffraction and photon-exchange in hadron-hadron, hadron-nucleus, and nucleus-nucleus collisions; Spin Physics; Low-$x$ PDFs, forward physics, and hadronic final states. This Workshop has been the XXVIII edition in the series of the workshop., Comment: The 2021 edition of the Low-$x$ International Workshop took place from September 26 to October 1 in Elba, Italy. Contains arXiv:2202.03724, arXiv:2111.04515, arXiv:2112.07827, arXiv:2110.05081, arXiv:2112.11054, arXiv:2112.13794, arXiv:2111.13916, arXiv:2201.06948, arXiv:2201.05224, arXiv:2202.04207, arXiv:2205.08785

Published

2022

15. Predictions for the Sivers Single-Spin Asymmetry from Holographic QCD

Author

Lyubovitskij, Valery E., Schmidt, Ivan, Brodsky, Stanley J., Lyubovitskij, Valery E., Schmidt, Ivan, and Brodsky, Stanley J.

Abstract

A new approach to nonperturbative QCD, holographic light-front QCD, provides a comprehensive model for hadron dynamics and spectroscopy, incorporating color confinement, a universal hadron mass scale, the prediction of a massless pion in the chiral limit, and connections between the spectroscopy of mesons, baryons and tetraquarks across the full hadron spectrum. In this article we present predictions for the Sivers asymmetry and related transverse momentum distributions for the proton based on the light-front wavefunctions of the baryon eigenstate predicted by holographic QCD., Comment: 9 pages, 10 figures

Published

2022

16. Onset of color transparency in holographic light-front QCD

Author

Brodsky, Stanley J., de Teramond, Guy F., Brodsky, Stanley J., and de Teramond, Guy F.

Abstract

The color transparency (CT) of a hadron, propagating with reduced absorption in a nucleus, is a fundamental property of QCD (quantum chromodynamics) reflecting its internal structure and effective size when it is produced at high transverse momentum, $Q$. CT has been confirmed in many experiments, such as semi-exclusive hard electroproduction, $e A \to e' \pi X$ for mesons produced at $Q^2 > 3 ~ {\rm GeV}^2$. However, a recent JLab (Jefferson Laboratory) measurement for a proton electroproduced in carbon $e\, {\rm C}\to e' p X$, where $X$ stands for the inclusive sum of all produced final states, fails to observe CT at $Q^2$ up to 14.2 GeV$^2$. In this paper, the onset of CT is determined by comparing the $Q^2$-dependence of the hadronic cross sections for the initial formation of a small color-singlet configuration using the generalized parton distributions from holographic light-front QCD. A critical dependence on the hadron's twist, $\tau$, the number of hadron constituents, is found for the onset of CT, with no significant effects from the nuclear medium. This effect can explain the absence of proton CT in the present kinematic range of the JLab experiment. The proton is predicted to have a "two-stage" color transparency with the onset of CT differing for the spin-conserving (twist-3, $\tau=3$) Dirac form factor with a higher onset in $Q^2$ for the spin-flip Pauli (twist-4) form factor. In contrast, the neutron is predicted to have a "one-stage" color transparency with the onset at higher $Q^2$ because of the dominance of its Pauli form factor. The model also predicts a strong dependence at low energies on the flavor of the quark current coupling to the hadron., Comment: 19 pages, 3 figures, contributed to the MDPI special issue for the special issue "The Future of Color Transparency, Hadronization and Short-Range Nucleon-Nucleon Correlation Studies"

Published

2022

17. Towards a single scale-dependent Pomeron in holographic light-front QCD

Author

Dosch, Hans Günter, de Téramond, Guy F., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., Deur, Alexandre, Dosch, Hans Günter, de Téramond, Guy F., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., and Deur, Alexandre

Abstract

The Pomeron Regge trajectory underlies the dynamics dependence of hadronic total cross sections and diffractive reactions at high energies. The physics of the Pomeron is closely related to the gluon distribution function and the gluon gravitational form factor of the target hadron. In this article we examine the scale dependence of the nonperturbative gluon distribution in the nucleon and the pion which was derived in a previous article [Phys. Rev. D 104, 114005 (2021)] in the framework of holographic light-front QCD and the Veneziano model. We argue that the QCD evolution of the gluon distribution function $g(x,\mu)$ to large $\mu^2$ leads to a single scale-dependent Pomeron. The resulting Pomeron trajectory $\alpha_P(t, \mu)$ not only depends on the momentum transfer squared $t$, but also on the physical scale $\mu$ of the amplitude, such as the virtuality $Q^2$ of the interacting photon in inclusive diffractive electroproduction. This can explain not only the $Q^2$ evolution of the proton structure function $F_2(x,Q^2)$ at small $x$, but also the observed energy and $Q^2$ dependence of high energy diffractive processes involving virtual photons up to LHC energies., Comment: 22 pages, 6 figures

Published

2022

18. 50 Years of Quantum Chromodynamics

Author

Gross, Franz, Klempt, Eberhard, Brodsky, Stanley J., Buras, Andrzej J., Burkert, Volker D., Heinrich, Gudrun, Jakobs, Karl, Meyer, Curtis A., Orginos, Kostas, Strickland, Michael, Stachel, Johanna, Zanderighi, Giulia, Brambilla, Nora, Braun-Munzinger, Peter, Britzger, Daniel, Capstick, Simon, Cohen, Tom, Crede, Volker, Constantinou, Martha, Davies, Christine, Del Debbio, Luigi, Denig, Achim, DeTar, Carleton, Deur, Alexandre, Dokshitzer, Yuri, Dosch, Hans Günter, Dudek, Jozef, Dunford, Monica, Epelbaum, Evgeny, Escobedo, Miguel A., Fritzsch, Harald, Fukushima, Kenji, Gambino, Paolo, Gillberg, Dag, Gottlieb, Steven, Grafstrom, Per, Grazzini, Massimiliano, Grube, Boris, Guskov, Alexey, Iijima, Toru, Ji, Xiangdong, Karsch, Frithjof, Kluth, Stefan, Kogut, John B., Krauss, Frank, Kumano, Shunzo, Leinweber, Derek, Leutwyler, Heinrich, Li, Hai-Bo, Li, Yang, Malaescu, Bogdan, Mariotti, Chiara, Maris, Pieter, Marzani, Simone, Melnitchouk, Wally, Messchendorp, Johan, Meyer, Harvey, Mitchell, Ryan Edward, Mondal, Chandan, Nerling, Frank, Neubert, Sebastian, Pappagallo, Marco, Pastore, Saori, Peláez, José R., Puckett, Andrew, Qiu, Jianwei, Rabbertz, Klaus, Ramos, Alberto, Rossi, Patrizia, Rustamov, Anar, Schäfer, Andreas, Scherer, Stefan, Schindler, Matthias, Schramm, Steven, Shifman, Mikhail, Shuryak, Edward, Sjöstrand, Torbjörn, Sterman, George, Stewart, Iain W., Stroth, Joachim, Swanson, Eric, de Téramond, Guy F., Thoma, Ulrike, Vairo, Antonio, van Dyk, Danny, Vary, James, Virto, Javier, Vos, Marcel, Weiss, Christian, Wobisch, Markus, Wu, Sau Lan, Young, Christopher, Yuan, Feng, Zhao, Xingbo, Zhou, Xiaorong, Gross, Franz, Klempt, Eberhard, Brodsky, Stanley J., Buras, Andrzej J., Burkert, Volker D., Heinrich, Gudrun, Jakobs, Karl, Meyer, Curtis A., Orginos, Kostas, Strickland, Michael, Stachel, Johanna, Zanderighi, Giulia, Brambilla, Nora, Braun-Munzinger, Peter, Britzger, Daniel, Capstick, Simon, Cohen, Tom, Crede, Volker, Constantinou, Martha, Davies, Christine, Del Debbio, Luigi, Denig, Achim, DeTar, Carleton, Deur, Alexandre, Dokshitzer, Yuri, Dosch, Hans Günter, Dudek, Jozef, Dunford, Monica, Epelbaum, Evgeny, Escobedo, Miguel A., Fritzsch, Harald, Fukushima, Kenji, Gambino, Paolo, Gillberg, Dag, Gottlieb, Steven, Grafstrom, Per, Grazzini, Massimiliano, Grube, Boris, Guskov, Alexey, Iijima, Toru, Ji, Xiangdong, Karsch, Frithjof, Kluth, Stefan, Kogut, John B., Krauss, Frank, Kumano, Shunzo, Leinweber, Derek, Leutwyler, Heinrich, Li, Hai-Bo, Li, Yang, Malaescu, Bogdan, Mariotti, Chiara, Maris, Pieter, Marzani, Simone, Melnitchouk, Wally, Messchendorp, Johan, Meyer, Harvey, Mitchell, Ryan Edward, Mondal, Chandan, Nerling, Frank, Neubert, Sebastian, Pappagallo, Marco, Pastore, Saori, Peláez, José R., Puckett, Andrew, Qiu, Jianwei, Rabbertz, Klaus, Ramos, Alberto, Rossi, Patrizia, Rustamov, Anar, Schäfer, Andreas, Scherer, Stefan, Schindler, Matthias, Schramm, Steven, Shifman, Mikhail, Shuryak, Edward, Sjöstrand, Torbjörn, Sterman, George, Stewart, Iain W., Stroth, Joachim, Swanson, Eric, de Téramond, Guy F., Thoma, Ulrike, Vairo, Antonio, van Dyk, Danny, Vary, James, Virto, Javier, Vos, Marcel, Weiss, Christian, Wobisch, Markus, Wu, Sau Lan, Young, Christopher, Yuan, Feng, Zhao, Xingbo, and Zhou, Xiaorong

Abstract

This paper presents a comprehensive review of both the theory and experimental successes of Quantum Chromodynamics, starting with its emergence as a well defined theory in 1972-73 and following developments and results up to the present day. Topics include a review of the earliest theoretical and experimental foundations; the fundamental constants of QCD; an introductory discussion of lattice QCD, the only known method for obtaining exact predictions from QCD; methods for approximating QCD, with special focus on effective field theories; QCD under extreme conditions; measurements and predictions of meson and baryon states; a special discussion of the structure of the nucleon; techniques for study of QCD at high energy, including treatment of jets and showers; measurements at colliders; weak decays and quark mixing; and a section on the future, which discusses new experimental facilities or upgrades currently funded. The paper is intended to provide a broad background for Ph.D. students and postdocs starting their career. Some contributions include personal accounts of how the ideas or experiments were developed., Comment: Invited volume for the EJPC; 567 pages if text/figures and 4783 references occupying about 160 additional pages. arXiv abstract abridged, for the complete abstract please see the full text

Published

2022

19. 50 Years of Quantum Chromodynamics

Author

Gross, Franz, Klempt, Eberhard, Brodsky, Stanley J., Buras, Andrzej J., Burkert, Volker D., Heinrich, Gudrun, Jakobs, Karl, Meyer, Curtis A., Orginos, Kostas, Strickland, Michael, Stachel, Johanna, Zanderighi, Giulia, Brambilla, Nora, Braun-Munzinger, Peter, Britzger, Daniel, Capstick, Simon, Cohen, Tom, Crede, Volker, Constantinou, Martha, Davies, Christine, Del Debbio, Luigi, Denig, Achim, DeTar, Carleton, Deur, Alexandre, Dokshitzer, Yuri, Dosch, Hans Günter, Dudek, Jozef, Dunford, Monica, Epelbaum, Evgeny, Escobedo, Miguel A., Fritzsch, Harald, Fukushima, Kenji, Gambino, Paolo, Gillberg, Dag, Gottlieb, Steven, Grafstrom, Per, Grazzini, Massimiliano, Grube, Boris, Guskov, Alexey, Iijima, Toru, Ji, Xiangdong, Karsch, Frithjof, Kluth, Stefan, Kogut, John B., Krauss, Frank, Kumano, Shunzo, Leinweber, Derek, Leutwyler, Heinrich, Li, Hai-Bo, Li, Yang, Malaescu, Bogdan, Mariotti, Chiara, Maris, Pieter, Marzani, Simone, Melnitchouk, Wally, Messchendorp, Johan, Meyer, Harvey, Mitchell, Ryan Edward, Mondal, Chandan, Nerling, Frank, Neubert, Sebastian, Pappagallo, Marco, Pastore, Saori, Peláez, José R., Puckett, Andrew, Qiu, Jianwei, Rabbertz, Klaus, Ramos, Alberto, Rossi, Patrizia, Rustamov, Anar, Schäfer, Andreas, Scherer, Stefan, Schindler, Matthias, Schramm, Steven, Shifman, Mikhail, Shuryak, Edward, Sjöstrand, Torbjörn, Sterman, George, Stewart, Iain W., Stroth, Joachim, Swanson, Eric, de Téramond, Guy F., Thoma, Ulrike, Vairo, Antonio, van Dyk, Danny, Vary, James, Virto, Javier, Vos, Marcel, Weiss, Christian, Wobisch, Markus, Wu, Sau Lan, Young, Christopher, Yuan, Feng, Zhao, Xingbo, Zhou, Xiaorong, Gross, Franz, Klempt, Eberhard, Brodsky, Stanley J., Buras, Andrzej J., Burkert, Volker D., Heinrich, Gudrun, Jakobs, Karl, Meyer, Curtis A., Orginos, Kostas, Strickland, Michael, Stachel, Johanna, Zanderighi, Giulia, Brambilla, Nora, Braun-Munzinger, Peter, Britzger, Daniel, Capstick, Simon, Cohen, Tom, Crede, Volker, Constantinou, Martha, Davies, Christine, Del Debbio, Luigi, Denig, Achim, DeTar, Carleton, Deur, Alexandre, Dokshitzer, Yuri, Dosch, Hans Günter, Dudek, Jozef, Dunford, Monica, Epelbaum, Evgeny, Escobedo, Miguel A., Fritzsch, Harald, Fukushima, Kenji, Gambino, Paolo, Gillberg, Dag, Gottlieb, Steven, Grafstrom, Per, Grazzini, Massimiliano, Grube, Boris, Guskov, Alexey, Iijima, Toru, Ji, Xiangdong, Karsch, Frithjof, Kluth, Stefan, Kogut, John B., Krauss, Frank, Kumano, Shunzo, Leinweber, Derek, Leutwyler, Heinrich, Li, Hai-Bo, Li, Yang, Malaescu, Bogdan, Mariotti, Chiara, Maris, Pieter, Marzani, Simone, Melnitchouk, Wally, Messchendorp, Johan, Meyer, Harvey, Mitchell, Ryan Edward, Mondal, Chandan, Nerling, Frank, Neubert, Sebastian, Pappagallo, Marco, Pastore, Saori, Peláez, José R., Puckett, Andrew, Qiu, Jianwei, Rabbertz, Klaus, Ramos, Alberto, Rossi, Patrizia, Rustamov, Anar, Schäfer, Andreas, Scherer, Stefan, Schindler, Matthias, Schramm, Steven, Shifman, Mikhail, Shuryak, Edward, Sjöstrand, Torbjörn, Sterman, George, Stewart, Iain W., Stroth, Joachim, Swanson, Eric, de Téramond, Guy F., Thoma, Ulrike, Vairo, Antonio, van Dyk, Danny, Vary, James, Virto, Javier, Vos, Marcel, Weiss, Christian, Wobisch, Markus, Wu, Sau Lan, Young, Christopher, Yuan, Feng, Zhao, Xingbo, and Zhou, Xiaorong

Abstract

This paper presents a comprehensive review of both the theory and experimental successes of Quantum Chromodynamics, starting with its emergence as a well defined theory in 1972-73 and following developments and results up to the present day. Topics include a review of the earliest theoretical and experimental foundations; the fundamental constants of QCD; an introductory discussion of lattice QCD, the only known method for obtaining exact predictions from QCD; methods for approximating QCD, with special focus on effective field theories; QCD under extreme conditions; measurements and predictions of meson and baryon states; a special discussion of the structure of the nucleon; techniques for study of QCD at high energy, including treatment of jets and showers; measurements at colliders; weak decays and quark mixing; and a section on the future, which discusses new experimental facilities or upgrades currently funded. The paper is intended to provide a broad background for Ph.D. students and postdocs starting their career. Some contributions include personal accounts of how the ideas or experiments were developed., Comment: Invited volume for the EJPC; 567 pages if text/figures and 4783 references occupying about 160 additional pages. arXiv abstract abridged, for the complete abstract please see the full text

Published

2022

20. Extending the Predictive Power of Perturbative QCD Using the Principle of Maximum Conformality and Bayesian Analysis

Author

Shen, Jian-Ming, Zhou, Zhi-Jian, Wang, Sheng-Quan, Yan, Jiang, Wu, Zhi-Fei, Wu, Xing-Gang, Brodsky, Stanley J., Shen, Jian-Ming, Zhou, Zhi-Jian, Wang, Sheng-Quan, Yan, Jiang, Wu, Zhi-Fei, Wu, Xing-Gang, and Brodsky, Stanley J.

Abstract

In addition to the evaluation of high-order loop contributions, the precision and predictive power of perturbative QCD (pQCD) predictions depends on two important issues: (1) how to achieve a reliable, convergent fixed-order series, and (2) how to reliably estimate the contributions of unknown higher-order terms. The recursive use of renormalization group equation, together with the Principle of Maximum Conformality (PMC), eliminates the renormalization scheme-and-scale ambiguities of the conventional pQCD series. The result is a conformal, scale-invariant series of finite order which also satisfies all of the principles of the renormalization group. In this paper we propose a novel Bayesian-based approach to estimate the size of the unknown higher order contributions based on an optimized analysis of probability distributions. We show that by using the PMC conformal series, in combination with the Bayesian analysis, one can consistently achieve high degree of reliability estimates for the unknown high order terms. Thus the predictive power of pQCD can be greatly improved. We illustrate this procedure for two pQCD observables: $R_{e^+e^-}$ and $R_\tau$, which are each known up to four loops in pQCD. Numerical analyses confirm that by using the scale-independent and more convergent PMC conformal series, one can achieve reliable Bayesian probability estimates for the unknown higher-order contributions., Comment: 14 pages, 4 figures, published version

Published

2022

21. Heavy quark contribution to the electromagnetic properties of the nucleon

Author

Brodsky, Stanley J., Lyubovitskij, Valery E., Schmidt, Ivan, Brodsky, Stanley J., Lyubovitskij, Valery E., and Schmidt, Ivan

Abstract

Quantum chromodynamics (QCD) predicts the existence of both nonperturbative intrinsic and perturbative extrinsic heavy quark contributions to the fundamental structure of hadrons. The existence of intrinsic charm at the 3-standard-deviation level in the proton has recently been established from structure function measurements by the NNPDF Collaboration. Here we revisit the physics of intrinsic heavy quarks using light-front holographic QCD (LFHQCD) - a novel comprehensive approach to hadron structure which provides detailed predictions for dynamical properties of the hadrons, such as form factors, distribution amplitudes, structure functions, etc. We will extend this nonperturbative light-front QCD approach to study the heavy quark-antiquark contribution to the electromagnetic properties of nucleon. Our framework is based on a study of the eigenfunctions of the QCD light-front Hamiltonian, the frame-independent light-front wave functions (LFWFs) underlying hadron dynamics. We analyze the heavy quark content in the proton, induced either directly by the nonperturbative $|uud+Q\bar Q\rangle$ Fock state or by the $|uud+g\rangle$ Fock state, where the gluon splits into a heavy quark-antiquark pair. The specific form of these LFWFs are derived from LFHQCD. Using these LFWFs, we construct light-front representations for the heavy quark-antiquark asymmetry, the electromagnetic form factors of nucleons induced by heavy quarks, including their magnetic moments and radii., Comment: 8 pages, 8 figures

Published

2022

22. Quantum Chromodynamics Resolution of the ATOMKI Anomaly in ${\rm {^4He}}$ Nuclear Transitions

Author

Kubarovsky, Valery, Kubarovsky, Valery, West, Jennifer Rittenhouse, Brodsky, Stanley J, Kubarovsky, Valery, Kubarovsky, Valery, West, Jennifer Rittenhouse, and Brodsky, Stanley J

Abstract

Recent observations of the angular correlation spectra in the decays $ {\rm ^4He}^*\to {\rm ^4He}+ e^+e^-$ and $ {\rm ^8Be}^*\to {\rm ^8Be}+ e^+e^-$ have been suggested as due to the creation and subsequent decay to an electron-positron pair of a new light particle with a mass of $\sim 17$ MeV. In this work, we present a calculation of the invariant $m_{e^+e^-}$ mass spectrum of the electromagnetic transition of an excited state of helium and estimate the differential and total width of the decay. We investigate the possibility that the source of the signal is an $e^+ e^-$ pair created by a new electromagnetic decay of $\rm ^4He$ caused by a proposed 12-quark hidden-color Fock state in the ${\rm {^4He}}$ nuclear wavefunction, the "hexadiquark.'' We find that we can fit the shape of the signal with the QCD Fock state at excitation energy ${\rm E^*}\simeq 17.9 $ MeV and a Gaussian form factor for the electromagnetic decay. We address the physical issues with the fit parameters using properties of the hexadiquark state. In light of this work, we emphasize the need for independent experimental confirmation or refutation of the ATOMKI results as well as further experiments to detect the proposed new excitation of ${\rm ^4He}$.

Published

2022

23. Proceedings of the Low-$x$ 2021 International Workshop

Author

Alcerro, L., Krintiras, G. K., Royon, C., Albrow, Michael G., Boettcher, Thomas, Brodsky, Stanley J., Celiberto, Francesco Giovanni, Cerci, Deniz Sunar, Cerci, Salim, Chachamis, G., Colferai, Dimitri, Duan, Weisong, Fabbri, Laura, Giuli, Francesco, Gras, Cristina Sánchez, Klein, Spencer R., Lewicki, Maciej P., Mäkelä, Toni, Jalilian-Marian, Jamal, Melnikov, Dmitry, Nemes, Frigyes, Lopes, Beatriz Ribeiro, Österberg, Kenneth, Petrov, Vladimir, Ragoni, Simone, Santimaria, M., Zhang, Zhiqing, Alcerro, L., Krintiras, G. K., Royon, C., Albrow, Michael G., Boettcher, Thomas, Brodsky, Stanley J., Celiberto, Francesco Giovanni, Cerci, Deniz Sunar, Cerci, Salim, Chachamis, G., Colferai, Dimitri, Duan, Weisong, Fabbri, Laura, Giuli, Francesco, Gras, Cristina Sánchez, Klein, Spencer R., Lewicki, Maciej P., Mäkelä, Toni, Jalilian-Marian, Jamal, Melnikov, Dmitry, Nemes, Frigyes, Lopes, Beatriz Ribeiro, Österberg, Kenneth, Petrov, Vladimir, Ragoni, Simone, Santimaria, M., and Zhang, Zhiqing

Abstract

The purpose of the Low-$x$ Workshop series is to stimulate discussions between experimentalists and theorists in diffractive hadronic physics, QCD dynamics at low $x$, parton saturation, and exciting problems in QCD at HERA, Tevatron, LHC, RHIC, and the future EIC. The central topics of the workshop, summarized in the current Proceedings, were: Diffraction in ep and e-ion collisions (including EIC physics); Diffraction and photon-exchange in hadron-hadron, hadron-nucleus, and nucleus-nucleus collisions; Spin Physics; Low-$x$ PDFs, forward physics, and hadronic final states. This Workshop has been the XXVIII edition in the series of the workshop., Comment: The 2021 edition of the Low-$x$ International Workshop took place from September 26 to October 1 in Elba, Italy. Contains arXiv:2202.03724, arXiv:2111.04515, arXiv:2112.07827, arXiv:2110.05081, arXiv:2112.11054, arXiv:2112.13794, arXiv:2111.13916, arXiv:2201.06948, arXiv:2201.05224, arXiv:2202.04207, arXiv:2205.08785

Published

2022

24. Towards a single scale-dependent Pomeron in holographic light-front QCD

Author

Dosch, Hans Günter, de Téramond, Guy F., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., Deur, Alexandre, Dosch, Hans Günter, de Téramond, Guy F., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., and Deur, Alexandre

Abstract

The Pomeron Regge trajectory underlies the dynamics dependence of hadronic total cross sections and diffractive reactions at high energies. The physics of the Pomeron is closely related to the gluon distribution function and the gluon gravitational form factor of the target hadron. In this article we examine the scale dependence of the nonperturbative gluon distribution in the nucleon and the pion which was derived in a previous article [Phys. Rev. D 104, 114005 (2021)] in the framework of holographic light-front QCD and the Veneziano model. We argue that the QCD evolution of the gluon distribution function $g(x,\mu)$ to large $\mu^2$ leads to a single scale-dependent Pomeron. The resulting Pomeron trajectory $\alpha_P(t, \mu)$ not only depends on the momentum transfer squared $t$, but also on the physical scale $\mu$ of the amplitude, such as the virtuality $Q^2$ of the interacting photon in inclusive diffractive electroproduction. This can explain not only the $Q^2$ evolution of the proton structure function $F_2(x,Q^2)$ at small $x$, but also the observed energy and $Q^2$ dependence of high energy diffractive processes involving virtual photons up to LHC energies., Comment: 22 pages, 6 figures

Published

2022

25. Supersymmetric and Other Novel Features of Hadron Physics from Light-Front Holography

Author

Brodsky, Stanley J. and Brodsky, Stanley J.

Abstract

I survey recent developments in hadron physics which follow from the application of superconformal quantum mechanics and light-front holography. This includes new insights into the physics of color confinement, chiral symmetry, the spectroscopy and dynamics of hadrons, as well as surprising supersymmetric relations between the masses of mesons, baryons, and tetraquarks. I also will discuss some novel features of QCD -- such as color transparency, hidden color, and asymmetric intrinsic heavy-quark phenomena. The elimination of renormalization scale ambiguities and the modification of QCD sum rules due to diffractive phenomena are also briefly reviewed., Comment: Contribution to the Proceedings of the 24th Workshop, "What Comes Beyond the Standard Models", Bled, July 3. - 11., 2021. arXiv admin note: substantial text overlap with arXiv:1512.05100, arXiv:1601.06328, arXiv:1611.07194; text overlap with arXiv:1709.01191, arXiv:1511.04142

Published

2021

26. PMC$_\infty$: Infinite-Order Scale-Setting method using the Principle of Maximum Conformality and preserving the Intrinsic Conformality

Author

Di Giustino, Leonardo, Brodsky, Stanley J., Wu, Xing-Gang, Wang, Sheng-Quan, Di Giustino, Leonardo, Brodsky, Stanley J., Wu, Xing-Gang, and Wang, Sheng-Quan

Abstract

We show results for Thrust and C-parameter in $e^+ e^-$ annihilation to 3 jets obtained using the recently developed new method for eliminating the scale ambiguity and the scheme dependence in pQCD namely the Infinite-Order Scale-Setting method using the Principle of Maximum Conformality (PMC$_\infty$). This method preserves an important underlying property of gauge theories: intrinsic Conformality (iCF). It leads to a remarkably efficient method to eliminate the conventional renormalization scale ambiguity at any order in pQCD. A comparison with Conventional Scale Setting method (CSS) is also shown., Comment: "Submission to SciPost", 11pages, 3 figures, proceedings , conference RADCOR 2021

Published

2021

27. Longitudinal dynamics and chiral symmetry breaking in holographic light-front QCD

Author

de Teramond, Guy F., Brodsky, Stanley J., de Teramond, Guy F., and Brodsky, Stanley J.

Abstract

The breaking of chiral symmetry in holographic light-front QCD is encoded in its longitudinal dynamics with its chiral limit protected by the superconformal algebraic structure which governs its transverse dynamics. The scale in the longitudinal light-front Hamiltonian determines the confinement strength in this direction: It is also responsible for most of the light meson ground state mass consistent with the Gell-Mann-Oakes-Renner constraint. Longitudinal confinement and the breaking of chiral symmetry are found to be different manifestations of the same underlying dynamics as found in 't Hooft large $N_C$ QCD(1 + 1) model., Comment: 10 pages, 4 figures, accepted for publication in PRD

Published

2021

28. Gluon matter distribution in the proton and pion from extended holographic light-front QCD

Author

de Téramond, Guy F., Dosch, H. G., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., Deur, Alexandre, de Téramond, Guy F., Dosch, H. G., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., and Deur, Alexandre

Abstract

The holographic light-front QCD framework provides a unified nonperturbative description of the hadron mass spectrum, form factors and quark distributions. In this article we extend holographic QCD in order to describe the gluonic distribution in both the proton and pion from the coupling of the metric fluctuations induced by the spin-two Pomeron with the energy momentum tensor in anti--de Sitter space, together with constraints imposed by the Veneziano model{\color{blue},} without additional free parameters. The gluonic and quark distributions are shown to have significantly different effective QCD scales., Comment: Version to be published in Phys. Rev. D

Published

2021

29. Longitudinal dynamics and chiral symmetry breaking in holographic light-front QCD

Author

de Teramond, Guy F., Brodsky, Stanley J., de Teramond, Guy F., and Brodsky, Stanley J.

Abstract

The breaking of chiral symmetry in holographic light-front QCD is encoded in its longitudinal dynamics with its chiral limit protected by the superconformal algebraic structure which governs its transverse dynamics. The scale in the longitudinal light-front Hamiltonian determines the confinement strength in this direction: It is also responsible for most of the light meson ground state mass consistent with the Gell-Mann-Oakes-Renner constraint. Longitudinal confinement and the breaking of chiral symmetry are found to be different manifestations of the same underlying dynamics as found in 't Hooft large $N_C$ QCD(1 + 1) model., Comment: 10 pages, 4 figures, accepted for publication in PRD

Published

2021

30. Supersymmetric and Other Novel Features of Hadron Physics from Light-Front Holography

Author

Brodsky, Stanley J. and Brodsky, Stanley J.

Abstract

I survey recent developments in hadron physics which follow from the application of superconformal quantum mechanics and light-front holography. This includes new insights into the physics of color confinement, chiral symmetry, the spectroscopy and dynamics of hadrons, as well as surprising supersymmetric relations between the masses of mesons, baryons, and tetraquarks. I also will discuss some novel features of QCD -- such as color transparency, hidden color, and asymmetric intrinsic heavy-quark phenomena. The elimination of renormalization scale ambiguities and the modification of QCD sum rules due to diffractive phenomena are also briefly reviewed., Comment: Contribution to the Proceedings of the 24th Workshop, "What Comes Beyond the Standard Models", Bled, July 3. - 11., 2021. arXiv admin note: substantial text overlap with arXiv:1512.05100, arXiv:1601.06328, arXiv:1611.07194; text overlap with arXiv:1709.01191, arXiv:1511.04142

Published

2021

31. Detailed Comparison of Renormalization Scale-Setting Procedures based on the Principle of Maximum Conformality

Author

Huang, Xu-Dong, Yan, Jiang, Ma, Hong-Hao, Di Giustino, Leonardo, Shen, Jian-Ming, Wu, Xing-Gang, Brodsky, Stanley J., Huang, Xu-Dong, Yan, Jiang, Ma, Hong-Hao, Di Giustino, Leonardo, Shen, Jian-Ming, Wu, Xing-Gang, and Brodsky, Stanley J.

Abstract

The {\it Principle of Maximum Conformality} (PMC), which generalizes the conventional Gell-Mann-Low method for scale-setting in perturbative QED to non-Abelian QCD, provides a rigorous method for achieving unambiguous scheme-independent, fixed-order predictions for physical observables consistent with the principles of the renormalization group. In addition to the original multi-scale-setting approach (PMCm), two variations of the PMC have been proposed to deal with ambiguities associated with the uncalculated higher order terms in the pQCD series, i.e. the single-scale-setting approach (PMCs) and the procedures based on "intrinsic conformality" (PMC$_\infty$). In this paper, we will give a detailed comparison of these PMC approaches by comparing their predictions for three important quantities $R_{e^+e^-}$, $R_{\tau}$, and $\Gamma(H \to b \bar{b})$ up to four-loop pQCD corrections. The PMCs approach determines an overall effective running coupling $\alpha_s(Q)$ by the recursive use of the renormalization group equation, whose argument $Q$ represents the actual momentum flow of the process. Our numerical results show that the PMCs method, which involves a somewhat simpler analysis, can serve as a reliable substitute for the full multi-scale PMCm method, and that it leads to more precise pQCD predictions with less residual scale dependence., Comment: 16 pages, 3 figures

Published

2021

32. Novel Corrections to the Momentum Sum Rule for Nuclear Structure Functions

Author

Brodsky, Stanley J., Lyubovitskij, Valery E., Schmidt, Ivan, Brodsky, Stanley J., Lyubovitskij, Valery E., and Schmidt, Ivan

Abstract

We address novel features of deep inelastic lepton scattering on nuclei at small Bjorken variable $x_{Bj}$. In this regime the lepton-nuclear cross section involves the interference between the standard lepton-quark scattering amplitude for the deep inelastic scattering (DIS) process on a single nucleon and a two-step process where diffractive scattering on a first nucleon combines with the amplitude for DIS on a second nucleon. The phases associated with the $t$-channel exchanges to the diffractive amplitude can produce either a destructive or constructive quantum-mechanical interference of the one-step and two-step amplitudes. This provides a mechanism regulating the respective amounts of shadowing suppression and anti-shadowing enhancement at low $x_{Bj}$. Furthermore, the standard leading-twist operator product and handbag diagram analyses of the forward virtual Compton amplitude on the nucleus are inapplicable, barring a conventional probabilistic interpretation. A main observable consequence is the impossibility of extracting momentum and spin sum rules from nuclear structure functions. We present numerical predictions supporting this picture and test them against DIS neutrino-nucleus and charged-lepton-nucleus scattering data., Comment: 7 pages, 3 figures. arXiv admin note: substantial text overlap with arXiv:1908.06317

Published

2021

33. PMC$_\infty$: Infinite-Order Scale-Setting method using the Principle of Maximum Conformality and preserving the Intrinsic Conformality

Author

Di Giustino, Leonardo, Brodsky, Stanley J., Wu, Xing-Gang, Wang, Sheng-Quan, Di Giustino, Leonardo, Brodsky, Stanley J., Wu, Xing-Gang, and Wang, Sheng-Quan

Abstract

We show results for Thrust and C-parameter in $e^+ e^-$ annihilation to 3 jets obtained using the recently developed new method for eliminating the scale ambiguity and the scheme dependence in pQCD namely the Infinite-Order Scale-Setting method using the Principle of Maximum Conformality (PMC$_\infty$). This method preserves an important underlying property of gauge theories: intrinsic Conformality (iCF). It leads to a remarkably efficient method to eliminate the conventional renormalization scale ambiguity at any order in pQCD. A comparison with Conventional Scale Setting method (CSS) is also shown., Comment: "Submission to SciPost", 11pages, 3 figures, proceedings , conference RADCOR 2021

Published

2021

34. Supersymmetric and Other Novel Features of Hadron Physics from Light-Front Holography

Author

Brodsky, Stanley J. and Brodsky, Stanley J.

Abstract

I survey recent developments in hadron physics which follow from the application of superconformal quantum mechanics and light-front holography. This includes new insights into the physics of color confinement, chiral symmetry, the spectroscopy and dynamics of hadrons, as well as surprising supersymmetric relations between the masses of mesons, baryons, and tetraquarks. I also will discuss some novel features of QCD -- such as color transparency, hidden color, and asymmetric intrinsic heavy-quark phenomena. The elimination of renormalization scale ambiguities and the modification of QCD sum rules due to diffractive phenomena are also briefly reviewed., Comment: Contribution to the Proceedings of the 24th Workshop, "What Comes Beyond the Standard Models", Bled, July 3. - 11., 2021. arXiv admin note: substantial text overlap with arXiv:1512.05100, arXiv:1601.06328, arXiv:1611.07194; text overlap with arXiv:1709.01191, arXiv:1511.04142

Published

2021

35. Gluon matter distribution in the proton and pion from extended holographic light-front QCD

Author

de Téramond, Guy F., Dosch, H. G., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., Deur, Alexandre, de Téramond, Guy F., Dosch, H. G., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., and Deur, Alexandre

Abstract

The holographic light-front QCD framework provides a unified nonperturbative description of the hadron mass spectrum, form factors and quark distributions. In this article we extend holographic QCD in order to describe the gluonic distribution in both the proton and pion from the coupling of the metric fluctuations induced by the spin-two Pomeron with the energy momentum tensor in anti--de Sitter space, together with constraints imposed by the Veneziano model{\color{blue},} without additional free parameters. The gluonic and quark distributions are shown to have significantly different effective QCD scales., Comment: Version to be published in Phys. Rev. D

Published

2021

36. The Diffractive Contribution to Deep Inelastic Lepton-Proton Scattering: Implications for QCD Momentum Sum Rules and Parton Distributions

Author

Brodsky, Stanley J., Lyubovitskij, Valery E., Schmidt, Ivan, Brodsky, Stanley J., Lyubovitskij, Valery E., and Schmidt, Ivan

Abstract

The cross section for deep inelastic lepton-proton scattering (DIS) $\ell p \to \ell' X$ includes a diffractive deep inelastic (DDIS) contribution $\ell p \to \ell' p' X$, in which the proton remains intact with a large longitudinal momentum fraction $x_F$ greater than 0.9 and small transverse momentum. The DDIS events, which can be identified with Pomeron exchange in the $t$-channel, account for approximately $10\%$ of all of the DIS events. Thus, when one measures DIS, one automatically includes the leading-twist Bjorken-scaling DDIS events as a contribution to the DIS cross section, whether or not the final-state proton $p'$ is detected. In such events, the missing momentum fraction $x_{p'} \sim 0.9$ carried by the final-state proton $p'$ in the DDIS events could be misidentified with the light-front momentum fraction carried by sea quarks or gluons in the protons' Fock structure. As we shall show in this article, the underlying QCD Pomeron-exchange amplitude which produces the DDIS events does not obey the operator product expansion nor satisfy momentum sum rules. Thus we conclude that the quark and gluon distributions measured in DIS experiments will be misidentified, unless the measurements explicitly exclude the DDIS events and that a correct determination of the parton distribution functions (PDFs) derived from the DIS data requires the explicit subtraction of the DDIS contribution from the full DIS cross section., Comment: 8 pages, 4 figures

Published

2021

37. Longitudinal dynamics and chiral symmetry breaking in holographic light-front QCD

Author

de Teramond, Guy F., Brodsky, Stanley J., de Teramond, Guy F., and Brodsky, Stanley J.

Abstract

The breaking of chiral symmetry in holographic light-front QCD is encoded in its longitudinal dynamics with its chiral limit protected by the superconformal algebraic structure which governs its transverse dynamics. The scale in the longitudinal light-front Hamiltonian determines the confinement strength in this direction: It is also responsible for most of the light meson ground state mass consistent with the Gell-Mann-Oakes-Renner constraint. Longitudinal confinement and the breaking of chiral symmetry are found to be different manifestations of the same underlying dynamics as found in 't Hooft large $N_C$ QCD(1 + 1) model., Comment: 10 pages, 4 figures, accepted for publication in PRD

Published

2021

38. PMC$_\infty$: Infinite-Order Scale-Setting method using the Principle of Maximum Conformality and preserving the Intrinsic Conformality

Author

Di Giustino, Leonardo, Brodsky, Stanley J., Wu, Xing-Gang, Wang, Sheng-Quan, Di Giustino, Leonardo, Brodsky, Stanley J., Wu, Xing-Gang, and Wang, Sheng-Quan

Abstract

We show results for Thrust and C-parameter in $e^+ e^-$ annihilation to 3 jets obtained using the recently developed new method for eliminating the scale ambiguity and the scheme dependence in pQCD namely the Infinite-Order Scale-Setting method using the Principle of Maximum Conformality (PMC$_\infty$). This method preserves an important underlying property of gauge theories: intrinsic Conformality (iCF). It leads to a remarkably efficient method to eliminate the conventional renormalization scale ambiguity at any order in pQCD. A comparison with Conventional Scale Setting method (CSS) is also shown., Comment: "Submission to SciPost", 11pages, 3 figures, proceedings , conference RADCOR 2021

Published

2021

39. Longitudinal dynamics and chiral symmetry breaking in holographic light-front QCD

Author

de Teramond, Guy F., Brodsky, Stanley J., de Teramond, Guy F., and Brodsky, Stanley J.

Abstract

The breaking of chiral symmetry in holographic light-front QCD is encoded in its longitudinal dynamics with its chiral limit protected by the superconformal algebraic structure which governs its transverse dynamics. The scale in the longitudinal light-front Hamiltonian determines the confinement strength in this direction: It is also responsible for most of the light meson ground state mass consistent with the Gell-Mann-Oakes-Renner constraint. Longitudinal confinement and the breaking of chiral symmetry are found to be different manifestations of the same underlying dynamics as found in 't Hooft large $N_C$ QCD(1 + 1) model., Comment: 10 pages, 4 figures, accepted for publication in PRD

Published

2021

40. Gluon matter distribution in the proton and pion from extended holographic light-front QCD

Author

de Téramond, Guy F., Dosch, H. G., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., Deur, Alexandre, de Téramond, Guy F., Dosch, H. G., Liu, Tianbo, Sufian, Raza Sabbir, Brodsky, Stanley J., and Deur, Alexandre

Abstract

The holographic light-front QCD framework provides a unified nonperturbative description of the hadron mass spectrum, form factors and quark distributions. In this article we extend holographic QCD in order to describe the gluonic distribution in both the proton and pion from the coupling of the metric fluctuations induced by the spin-two Pomeron with the energy momentum tensor in anti--de Sitter space, together with constraints imposed by the Veneziano model{\color{blue},} without additional free parameters. The gluonic and quark distributions are shown to have significantly different effective QCD scales., Comment: Version to be published in Phys. Rev. D

Published

2021

41. Comparing light-front quantization with instant-time quantization

Author

Mannheim, Philip D., Lowdon, Peter, Brodsky, Stanley J., Mannheim, Philip D., Lowdon, Peter, and Brodsky, Stanley J.

Abstract

We compare light-front quantization and instant-time quantization both at the level of operators and at the level of their Feynman diagram matrix elements. At the level of operators light-front quantization and instant-time quantization lead to equal light-front time commutation (or anticommutation) relations that appear to be quite different from equal instant-time commutation (or anticommutation) relations. Despite this we show that at unequal times instant-time and light-front commutation (or anticommutation) relations actually can be transformed into each other, with it only being the restriction to equal times that makes the commutation (or anticommutation) relations appear to be so different. While our results are valid for both bosons and fermions, for fermions there are subtleties associated with tip of the light cone contributions that need to be taken care of. At the level of Feynman diagrams we show for non-vacuum Feynman diagrams that the pole terms in four-dimensional light-front Feynman diagrams reproduce the three-dimensional light-front on-shell Hamiltonian Fock space formulation in which the light-front energy and light-front momentum are on shell. However, because of circle at infinity contributions we show that this equivalence fails for four-dimensional light-front vacuum tadpole diagrams. Then, precisely because of these circle at infinity contributions, light-front vacuum tadpole diagrams are not only nonzero, they are actually equal to instant-time vacuum tadpole diagrams. Light-front vacuum diagrams are not correctly describable by the on-shell Hamiltonian formalism, and thus not by the closely related infinite momentum frame prescription either. With the transformation from instant-time fields to light-front fields being a spacetime translation, not only are instant-time quantization and light-front quantization equivalent, they are unitarily equivalent., Comment: 72 pages, 2 figures. Expanded version of arXiv:1909.03548, includes discussion of light-front Lehmann representation and connection between light-front and instant-time Hamiltonians

Published

2020

42. Light-Front Holography and Supersymmetric Conformal Algebra: A Novel Approach to Hadron Spectroscopy, Structure, and Dynamics

Author

Brodsky, Stanley J., de Teramond, Guy F., Dosch, Hans Gunter, Brodsky, Stanley J., de Teramond, Guy F., and Dosch, Hans Gunter

Abstract

We give an overview of recent progress into the infrared structure of QCD based on the gauge/gravity correspondence and light-front quantization, where the color confining interaction for mesons and baryons is determined by an underlying superconformal algebraic structure. This new approach to hadron physics gives remarkable connections and predictions across the entire mass spectrum of hadrons and also describes the infrared behavior of the strong coupling. More recently, an extensive study of form factors, polarized and unpolarized parton distributions and the sea quark contribution to the nucleon has been carried out by extending the holographic formalism to incorporate the nonperturbative structure of Veneziano amplitudes. Contribution to the report "Strong QCD from Hadron Structure Experiments" Jefferson Lab Workshop, 5-9 November, 2019, Comment: 8 pages, 7 figures, Strong QCD from Hadron Structure Experiments, SLAC-PUB-17520. Jefferson Lab Workshop, 5-9 November, 2019

Published

2020

43. PMC$_\infty$: Infinite-Order Scale-Setting using the Principle of Maximum Conformality, A Remarkably Efficient Method for Eliminating Renormalization Scale Ambiguities for Perturbative QCD

Author

Di Giustino, Leonardo, Brodsky, Stanley J., Wang, Sheng-Quan, Wu, Xing-Gang, Di Giustino, Leonardo, Brodsky, Stanley J., Wang, Sheng-Quan, and Wu, Xing-Gang

Abstract

We identify a property of renormalizable SU(N)/U(1) gauge theories, the intrinsic Conformality ($iCF$), which underlies the scale invariance of physical observables and leads to a remarkably efficient method to solve the conventional renormalization scale ambiguity at every order in pQCD: the PMC$_\infty$. This new method reflects the underlying conformal properties displayed by pQCD at NNLO, eliminates the scheme dependence of pQCD predictions and is consistent with the general properties of the PMC (Principle of Maximum Conformality). We introduce a new method to identify conformal and $\beta$-terms which can be applied either to numerical or to theoretical calculations. We illustrate the PMC$_\infty$ for the thrust and C-parameter distributions in $e^+ e^-$ annihilation and then we show how to apply this new method to general observables in QCD. We point out how the implementation of the PMC$_\infty$ can significantly improve the precision of pQCD predictions; its implementation in multi-loop analysis also simplifies the calculation of higher orders corrections in a general renormalizable gauge theory., Comment: 10 pages, 6 figures

Published

2020

44. Constraints on charm-anticharm asymmetry in the nucleon from lattice QCD

Author

Sufian, Raza Sabbir, Liu, Tianbo, Alexandru, Andrei, Brodsky, Stanley J., de Téramond, Guy F., Dosch, Hans Günter, Draper, Terrence, Liu, Keh-Fei, Yang, Yi-Bo, Sufian, Raza Sabbir, Liu, Tianbo, Alexandru, Andrei, Brodsky, Stanley J., de Téramond, Guy F., Dosch, Hans Günter, Draper, Terrence, Liu, Keh-Fei, and Yang, Yi-Bo

Abstract

We present the first lattice QCD calculation of the charm quark contribution to the nucleon electromagnetic form factors $G^c_{E,M}(Q^2)$ in the momentum transfer range $0\leq Q^2 \leq 1.4$ $\rm GeV^2$. The quark mass dependence, finite lattice spacing and volume corrections are taken into account simultaneously based on the calculation on three gauge ensembles including one at the physical pion mass. The nonzero value of the charm magnetic moment $\mu^c_M=-0.00127(38)_{\rm stat}(5)_{\rm sys}$, as well as the Pauli form factor, reflects a nontrivial role of the charm sea in the nucleon spin structure. The nonzero $G^c_{E}(Q^2)$ indicates the existence of a nonvanishing asymmetric charm-anticharm sea in the nucleon. Performing a nonperturbative analysis based on holographic QCD and the generalized Veneziano model, we study the constraints on the $[c(x)-\bar{c}(x)]$ distribution from the lattice QCD results presented here. Our results provide complementary information and motivation for more detailed studies of physical observables that are sensitive to intrinsic charm and for future global analyses of parton distributions including asymmetric charm-anticharm distribution., Comment: Published version, Physics Letters B

Published

2020

45. Light-Front Holography and Supersymmetric Conformal Algebra: A Novel Approach to Hadron Spectroscopy, Structure, and Dynamics

Author

Brodsky, Stanley J., de Teramond, Guy F., Dosch, Hans Gunter, Brodsky, Stanley J., de Teramond, Guy F., and Dosch, Hans Gunter

Abstract

We give an overview of recent progress into the infrared structure of QCD based on the gauge/gravity correspondence and light-front quantization, where the color confining interaction for mesons and baryons is determined by an underlying superconformal algebraic structure. This new approach to hadron physics gives remarkable connections and predictions across the entire mass spectrum of hadrons and also describes the infrared behavior of the strong coupling. More recently, an extensive study of form factors, polarized and unpolarized parton distributions and the sea quark contribution to the nucleon has been carried out by extending the holographic formalism to incorporate the nonperturbative structure of Veneziano amplitudes. Contribution to the report "Strong QCD from Hadron Structure Experiments" Jefferson Lab Workshop, 5-9 November, 2019, Comment: 8 pages, 7 figures, Strong QCD from Hadron Structure Experiments, SLAC-PUB-17520. Jefferson Lab Workshop, 5-9 November, 2019

Published

2020

46. Constraints on charm-anticharm asymmetry in the nucleon from lattice QCD

Author

Sufian, Raza Sabbir, Liu, Tianbo, Alexandru, Andrei, Brodsky, Stanley J., de Téramond, Guy F., Dosch, Hans Günter, Draper, Terrence, Liu, Keh-Fei, Yang, Yi-Bo, Sufian, Raza Sabbir, Liu, Tianbo, Alexandru, Andrei, Brodsky, Stanley J., de Téramond, Guy F., Dosch, Hans Günter, Draper, Terrence, Liu, Keh-Fei, and Yang, Yi-Bo

Abstract

We present the first lattice QCD calculation of the charm quark contribution to the nucleon electromagnetic form factors $G^c_{E,M}(Q^2)$ in the momentum transfer range $0\leq Q^2 \leq 1.4$ $\rm GeV^2$. The quark mass dependence, finite lattice spacing and volume corrections are taken into account simultaneously based on the calculation on three gauge ensembles including one at the physical pion mass. The nonzero value of the charm magnetic moment $\mu^c_M=-0.00127(38)_{\rm stat}(5)_{\rm sys}$, as well as the Pauli form factor, reflects a nontrivial role of the charm sea in the nucleon spin structure. The nonzero $G^c_{E}(Q^2)$ indicates the existence of a nonvanishing asymmetric charm-anticharm sea in the nucleon. Performing a nonperturbative analysis based on holographic QCD and the generalized Veneziano model, we study the constraints on the $[c(x)-\bar{c}(x)]$ distribution from the lattice QCD results presented here. Our results provide complementary information and motivation for more detailed studies of physical observables that are sensitive to intrinsic charm and for future global analyses of parton distributions including asymmetric charm-anticharm distribution., Comment: Published version, Physics Letters B

Published

2020

47. PMC$_\infty$: Infinite-Order Scale-Setting using the Principle of Maximum Conformality, A Remarkably Efficient Method for Eliminating Renormalization Scale Ambiguities for Perturbative QCD

Author

Di Giustino, Leonardo, Brodsky, Stanley J., Wang, Sheng-Quan, Wu, Xing-Gang, Di Giustino, Leonardo, Brodsky, Stanley J., Wang, Sheng-Quan, and Wu, Xing-Gang

Abstract

We identify a property of renormalizable SU(N)/U(1) gauge theories, the intrinsic Conformality ($iCF$), which underlies the scale invariance of physical observables and leads to a remarkably efficient method to solve the conventional renormalization scale ambiguity at every order in pQCD: the PMC$_\infty$. This new method reflects the underlying conformal properties displayed by pQCD at NNLO, eliminates the scheme dependence of pQCD predictions and is consistent with the general properties of the PMC (Principle of Maximum Conformality). We introduce a new method to identify conformal and $\beta$-terms which can be applied either to numerical or to theoretical calculations. We illustrate the PMC$_\infty$ for the thrust and C-parameter distributions in $e^+ e^-$ annihilation and then we show how to apply this new method to general observables in QCD. We point out how the implementation of the PMC$_\infty$ can significantly improve the precision of pQCD predictions; its implementation in multi-loop analysis also simplifies the calculation of higher orders corrections in a general renormalizable gauge theory., Comment: 10 pages, 6 figures

Published

2020

48. Renormalization Scale Setting for Heavy Quark Pair Production in $e^+e^-$ Annihilation near the Threshold Region

Author

Wang, Sheng-Quan, Brodsky, Stanley J., Wu, Xing-Gang, Di Giustino, Leonardo, Shen, Jian-Ming, Wang, Sheng-Quan, Brodsky, Stanley J., Wu, Xing-Gang, Di Giustino, Leonardo, and Shen, Jian-Ming

Abstract

Heavy fermion pair production in $e^+e^-$ annihilation is a fundamental process in hadron physics and is of considerable interest for various phenomena. In this paper, we will apply the Principle of Maximum Conformality (PMC) to provide a comprehensive analysis of these processes. The PMC provides a systematic, unambiguous method for determining the renormalization scales of the QCD coupling constant for single-scale and multiple-scale applications. The resulting predictions eliminate any renormalization scheme-and-scale ambiguities, eliminate the factorial renormalon divergences, and are consistent with the requirements of the renormalization group. It is remarkable that two distinctly different scales are determined by using the PMC for heavy fermion pair production near the threshold region. One scale is the order of the fermion mass $m_f$, which enters the hard virtual corrections, and the other scale is of order $ v\,m_f$, where $v$ is the quark velocity, which enters the Coulomb rescattering amplitude. The PMC scales yield the correct physical behavior and reflect the virtuality of the propagating gluons (photons) for the QCD (QED) processes. Moreover, we demonstrate the consistency of PMC scale setting from QCD to QED. Perfect agreement between the Abelian unambiguous Gell-Mann-Low and the PMC scale-setting methods in the limit of zero number of colors is demonstrated., Comment: 8 pages, 6 figures, published version

Published

2020

49. Reanalysis of the top-quark pair hadroproduction and a precise determination of the top-quark pole mass at the LHC

Author

Wang, Sheng-Quan, Wu, Xing-Gang, Shen, Jian-Ming, Brodsky, Stanley J., Wang, Sheng-Quan, Wu, Xing-Gang, Shen, Jian-Ming, and Brodsky, Stanley J.

Abstract

In this paper, we calculate the $t\bar{t}$ pQCD production cross-section at NNLO and determine the top-quark pole mass from recent measurements at the LHC at $\sqrt{S}=13$ TeV center-of-mass energy to high precision by applying the Principle of Maximum Conformality (PMC). The PMC provides a systematic method which rigorously eliminates QCD renormalization scale ambiguities by summing the nonconformal $\beta$ contributions into the QCD coupling constant. The PMC predictions satisfy the requirements of renormalization group invariance, including renormalization scheme independence, and the PMC scales accurately reflect the virtuality of the underlying production subprocesses. By using the PMC, an improved prediction for the $t\bar{t}$ production cross-section is obtained without scale ambiguities, which in turn provides a precise value for the top-quark pole mass. Moreover, the predictive power of PMC calculations that the magnitude of higher-order PMC predictions are well within the error bars predicted from the known lower-order has been demonstrated for the top-quark pair production. The resulting determination of the top-quark pole mass $m_t^{\rm pole}=172.5\pm1.4$ GeV from the LHC measurement at $\sqrt{S}=13$ TeV is in agreement with the current world average cited by the Particle Data Group (PDG). The PMC prediction provides an important high-precision test of the consistency of pQCD and the SM at $\sqrt{S}=13$ TeV with previous LHC measurements at lower CM energies., Comment: 8 pages, 5 figures

Published

2020

50. Scale-Fixed Predictions for $\gamma + \eta_c$ production in electron-positron collisions at NNLO in perturbative QCD

Author

Yu, Huai-Min, Sang, Wen-Long, Huang, Xu-Dong, Zeng, Jun, Wu, Xing-Gang, Brodsky, Stanley J., Yu, Huai-Min, Sang, Wen-Long, Huang, Xu-Dong, Zeng, Jun, Wu, Xing-Gang, and Brodsky, Stanley J.

Abstract

In the paper, we present QCD predictions for $\eta_{c} + \gamma$ production at an electron-position collider up to next-to-next-to-leading order (NNLO) accuracy without renormalization scale ambiguities. The NNLO total cross-section for $e^{+}+e^{-}\to\gamma+\eta_{c}$ using the conventional scale-setting approach has large renormalization scale ambiguities, usually estimated by choosing the renormalization scale to be the $e^+ e^-$ center-of-mass collision energy $\sqrt{s}$. The Principle of Maximum Conformality (PMC) provides a systematic way to eliminate such renormalization scale ambiguities by summing the nonconformal $\beta$ contributions into the QCD coupling $\alpha_s(Q^2)$. The renormalization group equation then sets the value of $\alpha_s$ for the process. The PMC renormalization scale reflects the virtuality of the underlying process, and the resulting predictions satisfy all of the requirements of renormalization group invariance, including renormalization scheme invariance. After applying the PMC, we obtain a scale-and-scheme independent prediction, $\sigma|_{\rm NNLO, PMC}\simeq 41.18$ fb for $\sqrt{s}$=10.6 GeV. The resulting pQCD series matches the series for conformal theory and thus has no divergent renormalon contributions. The large $K$ factor which contributes to this process reinforces the importance of uncalculated NNNLO and higher-order terms. Using the PMC scale-and-scheme independent conformal series and the $\rm Pad\acute{e}$ approximation approach, we predict $\sigma|_{\rm NNNLO, PMC+Pade} \simeq 21.36$ fb, which is consistent with the recent BELLE measurement $\sigma^{\rm obs}$=$16.58^{+10.51}_{-9.93}$ fb at $\sqrt{s} \simeq 10.6$ GeV. This procedure also provides a first estimate of the NNNLO contribution., Comment: 8 pages, 5 figures. Discussions improved and references updated. Revised version to be published in JHEP

Published

2020